Power supply arrangement comprising a DC/DC converter

Abstract

The invention relates to a power supply arrangement (2, 3) comprising a DC/DC converter (3) including:

Description

[0001] The invention relates to a power supply arrangement comprising a DC/DC converter. Such a power supply arrangement can be used in power supplies or (switched-mode) power supplies or charging devices (for example for mobile radios), in which an AC mains voltage is converted by an AC/DC converter and by the DC/DC converter into a DC supply voltage.

[0002] Converters with asymmetric half-bridge topologies are basically known. Known converters have zero voltage switching of the half-bridge switch elements. The switch elements are controlled by pulse width modulated control signals with a constant frequency. An optimal resetting of the transformer core is guaranteed. The leakage inductance of the transformer is used. The power load of the switch elements is reduced compared to the otherwise often used blocking converters (flyback converters). The EMI load (Electro Magnetic Interference) by asymmetric half-bridge converters is small.

[0003] A DC/DC converter arranged as an asymmetric half-bridge converter is known from U.S. Pat. No. 5,808,879 (FIG. 9), comprising a half bridge which includes a first and a second switch element (switch elements arranged as MOSFET-transistors) to which a DC voltage is applied i.e. the half bridge is arranged between a first DC voltage potential (“+” supply potential) and a second DC voltage potential (“−” reference potential, customarily equal to the ground potential). A circuit branch which comprises the primary winding of a transformer and a capacitor connected in series to the primary winding is connected in parallel to the first switch element which is connected to the first DC voltage potential. The capacitor is arranged between the connection point of the two switch elements and the primary winding. The primary winding of the transformer is arranged between the capacitor and the first DC voltage potential. A capacitive output filter is arranged in parallel to the output of the DC/DC converter. Between the capacitive output filter and the secondary winding of the transformer is arranged a diode. In case of energy transport from the primary side to the secondary side of the converter, a current will flow on the primary side, on the one hand, through the circuit branch connected in parallel to the switched-off (opened) first switch element, which circuit branch includes the primary winding and the capacitor and, on the other hand, also through the switched-on (closed) second switch element.

[0004] The converter described in U.S. Pat. No. 5,808,879 is advantageous in that over-current protection is only necessary for the second switch element. Over-currents which lead to the destruction of a switch element may occur during the switch-on phase of the converter and in case of overload. When the converter is switched on, the capacitor connected in series to the primary winding of the transformer does not yet have charge. Accordingly, the current flowing through the second switch element by which the capacitor is charged strongly increases in the phase shortly after it has been switched on. Accordingly, the second switch element is to be protected against over-currents in the switch-on phase of the converter. The switch element that is switched on and through which a current flows during the energy transfer from the primary side to the secondary side of the transformer is to be protected from over-currents in the case of overload. With the converter described here it is the second switch element.

[0005] The converter described in U.S. Pat. No. 5,808,879 furthermore has the advantage that the so-termed burst mode is automatically set by measuring the input power on the primary side of the transformer. The burst mode is used with a reduced power consumption for a standby operation of a load and is characterized in that the converter is alternately switched off and on for a brief period of time. The converter is switched off especially when the two switch elements are simultaneously switched off. While the converter is switched off, the no-load losses of the converter are minimal. When the converter is switched on, the output capacitor is charged until the output voltage has reached its set value. This sequence of switching on and off causes a low power consumption with an available output voltage. The burst mode is only sensible with a small load, because otherwise the output voltage sharply drops during pauses of operation. For automatically activating and deactivating the burst mode, the input or output power of the converter can be measured. Measuring the input power is more cost effective compared to measuring the output power, because the electric isolation of output side and input side by the transformer need not be bridged. The input power is preferably measured by measuring the input voltage and the input current. The measurement of the input current is possible here simply by measuring the current flowing through the second switch element while only a measuring resistor (shunt resistor) is connected in series to the second switch element, which is so simple here because the second switch element is the only current path to the DC voltage potential coupled to the second switch element. It is particularly simple to measure the current when the measuring resistor is connected to the respective reference potential (ground potential) i.e. the voltage on the measuring resistor can be measured relative to the reference potential.

[0006] From the conference contribution by Phua Chee Heng, Ramesh Oruganti, “Family of Two-Switch Soft-Switched Asymmetrical PWM DC/DC Converters”, PESC 1994 is known a still older version of an asymmetrical half-bridge converter which is referred to as a buck reset TRC2-converter. This converter, however, does not have the two above-mentioned advantages of the converter of FIG. 9 of U.S. Pat. No. 5,808,879.

[0007] The converters described can be designed with or without a control of the output voltage. If a control is provided, the converter output voltage is customarily fed back via a feedback branch with an optocoupler, which leads to increased cost and is applied to a primary side control circuit which adapts the duty cycle of the control signals applied to the switch elements in dependence on the current converter output voltage, so that the output voltage is kept constant. Without a control of the output voltage, increased fluctuations of the converter output voltage especially in case of fluctuations of the input voltage and of the output current are to be taken into the bargain.

[0008] It is an object of the invention to provide an asymmetrical half-bridge converter which has said advantages of the converter from U.S. Pat. No. 5,808,879, generates an output voltage with a smallest possible tolerance area and is furthermore highly cost-effective.

[0009] The object is achieved by a converter as claimed in claim 1. Provided that a primary-side control loop is included, an optocoupler is not necessary for realizing a feedback path, so that this is the saving of cost. The primary-side control loop is now realized by circuit arrangement components located on the primary side.

[0010] In a primary-side control loop particularly the voltage which is impressed during the transmission of power from the primary side to the secondary side of the primary winding of the transformer is set to a predefinable fixed value, preferably by adapting the duty cycle of the control signals to be used for controlling the switch elements.

[0011] When operated in uncontrolled manner the voltage on the primary winding and thus the output voltage of the DC/DC converter depending on it would fluctuate intolerably. Reasons for this are fluctuations of the input voltage, ripple of the input voltage and tolerances of the adjustable duty cycle based on production engineering tolerances of the control circuit which is particularly realized by an integrated circuit. To counteract fluctuations of the voltage on the primary winding or the converter output voltage, respectively, the primary-side control is used. The control signals to be adjusted for the primary-side control for controlling the switch elements are particularly pulse width modulated i.e. an adjustment of the control signals is made by adjustment of the respective duty cycle. Claim 2 shows a variant with an additional capacitor.

[0012] Claim 3 indicates in how far the power supply arrangement according to the invention can be arranged for obtaining a measuring value for the voltage on the primary winding when the DC/DC converter is switched on by the tapping of the potential between the primary winding and the capacitive element. Since the second switch element coupled to the second DC voltage potential is turned on during energy transfer, and the capacitive element is coupled to the first DC voltage potential, the potential represents between the capacitive element and the primary winding, irrespective of the instant in a switching cycle, the voltage on the primary winding of the transformer during energy transfer from the primary side to the secondary side, so that the converter output voltage is set with a sufficient tolerance for many applications (for example, charging devices for mobile telephones) in this manner. Basically, the arrangement also works with a primary-side control when there is an energy transfer from the primary side to the secondary side in the other state of the half bridge or when there is full-wave rectifying in the two states of the half bridge.

[0013] The claims 4 to 7 define embodiments of the power supply arrangement according to the invention. Further modifications of the embodiment as claimed in claim 6 comprise the use of inductive output filters and/or a full-wave rectifying. Claim 8 relates to a DC/DC converter according to the invention. The claims 9 and 10 relate to the circuit arrangement according to the invention and the DC/DC converter according to the invention, which converter makes the use possible of a primary-side control loop. Claim 11 relates to an electric device with a circuit arrangement according to the invention, which device is, for example, a charging device for a mobile telephone.

[0014] These and other aspects of the invention are apparent from and will be elucidated with reference to the examples of embodiment described hereinafter.

[0015] In the drawings:

[0016] FIG. 1 shows an electric device with a power supply arrangement according to the invention,

[0017] FIG. 2 shows a DC/DC converter used in the power supply arrangement,

[0018] FIG. 3 shows the converter of FIG. 2 with a primary-side control loop and

[0019] FIG. 4 shows a variant of the converter shown in FIG. 3.

[0020] FIG. 1 shows electric device 1 with a power supply arrangement which comprises an AC-DC converter 2 and a DC/DC converter 3. The electric device 1 converts an AC mains voltage (for example 230 volts) UAC into a DC supply voltage U0. First the AC mains voltage UAC is converted into a DC voltage Vi by the AC/DC converter 2, which DC voltage Vi is used as an input voltage for the DC/DC converter 3 and is converted by it into the DC supply voltage U0. The electric device 1 is a (switched-mode) power supply or, preferably, a charging device for mobile telephones. AC/DC converters are known so that the converter 2 will not be further discussed. The invention rather relates to the realization of the DC/DC converter 3 which is explained in more detail by means of the FIGS. 2 to 4.

[0021] FIG. 2 shows a first variant of the DC/DC converter 3. The input of this converter is supplied with the DC voltage Vi which is applied to the series combination of two switch elements 4 and 5. The positive supply potential (+) is then connected to a terminal of the switch element 4. The reference potential (−), i.e. the ground potential is connected to the switch element 5 whose other terminal is connected to the switch element 4. The circuit branch comprising a capacitive element 6 and a primary winding of a transformer 7 connected in series to the capacitive element 6, the direction of winding (orientation/polarity of the windings) of which transformer 7 is featured by dots, is connected in parallel to the switch element 4. A terminal of the secondary winding of the transformer 7 is connected to the anode of a diode 8. Between the cathode of the diode 8 and the other terminal of the secondary winding of the transformer 7 is arranged a capacitive output filter here in the form of a capacitor 9. The DC output voltage U0 of the DC/DC converter 3 is tapped from the capacitive output filter 9.

[0022] The switch elements 4 and 5 are alternately switched on or off with a predefined duty cycle. When the switch element 4 is switched off and switch element is switched on, there is a transport of energy from the primary side of the converter 3 via the transformer 7 to the secondary side of the converter 3. The DC voltage Vi then generates a current flowing through the circuit branch comprising the capacitive element 6 and the primary winding of the transformer 7 and also through the switch element 5. A voltage V0 on the primary winding of the transformer 7 then drops as is shown. With the selected direction of the winding of the transformer 7 and the available polarity of the diode 8 a current is then caused to flow through the diode 8 on the secondary winding of the transformer 7. The winding direction of the primary and secondary windings of the transformer is selected so that there is a flow of energy from the primary side to the secondary side of the transformer 7 in essence when there is a current flowing through the second switch element 5. As the current flows through the diode 8, the capacitor 9 is charged and/or a current is caused to flow to a connected load.

[0023] If the switch element 4 is turned on and the switch element 5 is turned off, the polarity of the voltage V0 on the primary winding of the transformer 7 is reversed and a current flows through the capacitive element 6, the switch element 4 and the primary winding of the transformer 7. In this operating state of the converter 3 the magnetization of the core of the transformer 7 is reduced (reset of the transformer core).

[0024] FIG. 3 shows the DC/DC converter as shown in FIG. 2 extended by a primary-side control loop. This control loop implies that a point between the capacitive element 6 and the primary winding of the transformer 7 is connected to an input of a control circuit 10, so that the potential Vp1 present at the respective point and representing the voltage V0 on the primary winding of the transformer 7, is applied to the control circuit. The control circuit 10 generates in dependence on potential Vp1 a control signal a1 for controlling the switch element 4 and a control signal a2 for controlling the switch element 5. The duty cycle of the control signals a1 and a2 is set and adapted by the control circuit 10, so that the voltage V0 on the primary winding of the transformer 7 drops when energy flows from the primary side to the secondary side of the converter 3, is controlled to a predefinable voltage value. This control provides that the output voltage U0 which depends on the voltage V0 is set. The primary-side control loop counteracts an undesired influence of fluctuations of the input voltage Vi, of a ripple (more particularly 100 Hz) and of inaccuracies during the setting of the duty cycle of the control signals a1 and a2 based on manufacturing tolerances for the control circuit 10 which is customarily realized by means of an integrated circuit, so that a usable DC output voltage U0 is rendered available by means of the converter 3. In a preferred embodiment the control is only converted by setting the duty cycle of the control signals a1 and a2. Basically, however, an adaptation of the frequency of the control signals a1 and a2 to said purpose is also possible, which, however, increases the complexity of the primary-side control loop. In a variant of the circuit a point between the capacitor 6 and the primary winding of the transformer 7 is connected to the reference potential by means of a further capacitor 11 (connections to the capacitor 11 are shown in a dashed line).

[0025] FIG. 4 shows a variant of the DC/DC converter 3. The basic structure is highly similar to the structure of converter 3. A DC voltage Vi is applied to two series-arranged switch elements 20 and 21, the supply potential (+) being connected to the switch element 20 and the reference potential (−) to the switch element 21. In the present case, however, the switch element 21 of the circuit branch, which switch element is connected to the reference potential, is connected in parallel to a series combination of the primary winding of a transformer 23 and a capacitive element 22. A diode 24 having its forward direction in the direction of the converter output is arranged between a capacitive output filter 25 realized by a capacitor 25 and the secondary winding of the transformer 23. The converter output voltage U0 is tapped from the capacitor 25.

[0026] Contrary to FIG. 3, the primary winding and the secondary winding of the transformer 23 now have reversed polarities. Accordingly, there is an energy transfer from the primary side to the secondary side of the converter 3 when the switch element 20 is turned off and the switch element 21 is turned on. A current then flows through the primary winding of the transformer 23, through the switch element 21 and through the capacitive element 22. On the primary winding 23 a voltage V0 drops in the direction shown in the drawing, so that a current flows through the diode 24 into the capacitor and/or into a load connected to the output of the converter 3. The energy then flowing from the primary side to the secondary side is supplied by the capacitive element 22. This element is charged when the switch element 20 is turned off and the switch element 21 is turned on, so that a current generated by the voltage Vi flows through the switch element 20, the primary winding of the transformer 23 and the capacitive element 22, while there is no energy transfer from the primary side to the secondary side of the converter 3 through the primary winding of the transformer when the current flows in this direction.

[0027] Also the converter variant shown in FIG. 4 has a primary-side control loop. This implies that a potential Vp2 present between the primary winding of the transformer 23 and the capacitive element 22 is tapped and applied to the control circuit 26. This potential Vp2, which represents the voltage V0 present on the primary winding of the transformer 23 when there is a flow of energy from the primary side to the secondary side of the converter 3, is controlled to a predefinable value by means of a setting of the duty cycle of the control signals b1 and b2 which are used for controlling the switch elements 20 and 21 respectively, and are generated by the control circuit 26 i.e. also the voltage V0 is controlled at a predefinable value. Also with the variant shown in FIG. 4 an additional capacitor (not shown) may optionally be inserted, which additional capacitor then connects a point between the capacitor 22 and the primary winding of the transformer 23 to the supply potential.

[0028] The converter variants shown in FIGS. 2 to 4 are advantageous in that the voltage V0 constantly to be controlled at a predefinable value, which voltage V0 is present on the primary winding of the transformer 7 or transformer 23 respectively, during an energy transfer from the primary side to the secondary side of the converter, is represented by the potential Vp1 or Vp2 respectively, irrespective of the point of time in a switching cycle; these potentials may be used as a controlled variable. This is made possible because the capacitive element 6 is connected to the supply potential (+) or the reference potential (−) respectively, and, on the other hand, a terminal of the primary winding of the transformer 7 or of the transformer 23 respectively, is connected to the terminal between the switch elements 4 and 5 or 20 and 21. In the converter variants shown in FIGS. 2 and 3 only one of the switch elements of the respective half bridge, that is switch element 5, can be provided with an overflow protection which protects against overflows in the initial phase and protects when the converter 3 has an overload. The converter in FIG. 4 on the other hand needs an overflow protection element in the two switch elements 20 and 21 so that switch element 20 is protected against overflows in the initial phase and switch element 21 is protected against overload of the converter.

[0029] The converter variants shown in FIGS. 2 and 3 are furthermore advantageous in that the input power of the converter 3 can be measured by measuring the voltage Vi and the current flowing through the switch element 4, so that a measuring resistor (shunt) (not shown) is arranged between the switch element 5 and the reference potential (ground potential), while the current can easily and reliably be measured by means of a measuring resistor connected to ground. Furthermore, the examples of embodiment in FIGS. 3 and 4 may basically also be modified so that another direction of winding of the transformer 7 is chosen.

Claims

1. A power supply arrangement (2, 3) comprising a DC/DC converter (3) including

a half bridge comprising a first (4, 21) and a second (5, 20) switch element and when the power supply arrangement (2, 3) is in operation is connected between a first and a second DC voltage potential,

a transformer (7, 23) whose primary winding together with a first capacitive element (6, 22) is included in a circuit branch connected in parallel to the first switch element (4, 21), the capacitive element in the circuit branch being connected in series to the primary winding and

a primary-side control loop for controlling the voltage (V0) on the primary winding of the transformer (7, 23) by adapting control signals (a1, a2, b1, b2) for the switch elements.

2. A power supply arrangement as claimed in claim 1, characterized in that the connection between the first capacitive element (6) and the primary winding is connected by a second capacitive element (11) to the DC voltage potential (−) which is coupled to a terminal of the second switch element (5).

3. A power supply arrangement as claimed in claim 1 or 2, characterized in that a terminal of the first capacitive element (6, 22) is coupled to the first DC voltage potential and a terminal of the second switch element (5, 20) is coupled to the second DC voltage potential.

4. A power supply arrangement as claimed in claim 3, characterized in that the first switch element (4) is coupled to a supply potential (+) and the second switch element (5) is coupled to a reference potential (−) and in that an energy transport takes place from the primary side to the secondary side when the first (4) switch element is turned off and the second switch element (5) is turned on.

5. A power supply arrangement as claimed in claim 3, characterized in that the first switch element (21) is coupled to a reference potential (−) and the second switch element (20) is coupled to a reference potential (+) and in that there is an energy transport from the primary side to the secondary side when the first switch element (21) is turned on and the second switch element (20) is turned off.

6. A power supply arrangement as claimed in one of the claims 1 to 5, characterized in that a terminal of the primary winding is connected to a point between the first (5, 21) and the second (4, 20) switch element, in that the other terminal of the primary winding is connected to a terminal of the first capacitive element (6, 22) and in that a control of a potential (Vp1, Vp2) is provided between the primary winding and the capacitive element.

7. A power supply arrangement as claimed in one of the claims 1 to 6, characterized in that a diode (8, 24) and a capacitive output filter (9, 25) are arranged on the secondary side of the transformer (7, 23) so that, when energy flows from the primary side to the secondary side of the transformer (7, 23) a current flows through the diode (8, 24) to the capacitive output filter (9, 25).

8. A DC/DC converter (3) including

a half bridge comprising a first (4, 21) and a second (5, 20) switch element and when the converter (3) is in operation is connected between a first and a second DC voltage potential,

a transformer (7, 23) whose primary winding together with a capacitive element (6, 22) is included in a circuit branch connected in parallel to the first switch element (4, 21), the capacitive element in the circuit branch being connected in series to the primary winding and

a primary-side control loop for controlling the voltage (V0) on the primary winding of the transformer (7, 23) by adapting control signals (a1, a2, b1, b2) for the switch elements.

9. A power supply arrangement comprising a DC/DC converter (3) including

a half bridge comprising a first (4) and a second (5) switch element and when the power supply arrangement is in operation is connected between a supply potential (+) and a reference potential (−),

a transformer (7) whose primary winding together with a capacitive element (6) is included in a circuit branch connected in parallel to the first switch element (4), the capacitive element in the circuit branch being connected in series to the primary winding and in which a terminal of the capacitive element (6) is connected to the supply potential (+) and a terminal of the second switch element (5) is connected to the reference potential (−) and in which the winding direction of the primary and secondary winding of the transformer is selected so that the energy flow from the primary side to the secondary side of the transformer (7) takes place when a current flows through the second switch element (5).

10. A DC/DC converter comprising

a half bridge comprising a first (4) and a second (5) switch element and when the power supply arrangement is in operation is connected between a supply potential (+) and a reference potential (−),

a transformer (7) whose primary winding together with a capacitive element (6) is included in a circuit branch connected in parallel to the first switch element (4), the capacitive element in the circuit branch being connected in series to the primary winding and in which a terminal of the capacitive element (6) is connected to the supply potential (+) and a terminal of the second switch element (5) is connected to the reference potential (−) and in which the winding direction of the primary and secondary windings of the transformer is selected so that an energy flow from the primary side to the secondary side of the transformer (7) takes place, in essence, when a current flows through the second switch element (5).

11. An electric device (1) for converting an AC voltage (UAC) into a DC supply voltage (U0), comprising a power supply arrangement (2, 3) as claimed in one of the claims 1 to 6 or as claimed in claim 8.